KR101317746B1 - Ofdm transmitter and ofdm transmission method - Google Patents

Abstract

The OFDM transmitter 10 includes a subcarrier selection unit 90, a modulation unit 30, a signal generation unit 50, a D / A converter 60, and an amplitude control unit 70. The subcarrier selection unit 90 selects a plurality of subcarriers used for transmission of digital data from subcarrier groups having an orthogonal relationship with each other. The modulation unit 30 divides the digital data according to the number of subcarriers selected by the subcarrier selection unit 90. In addition, the modulation unit 30 modulates a plurality of subcarriers based on the divided digital data to generate a plurality of modulation subcarriers. The signal generation unit 50 generates a digital OFDM signal by multiplexing a plurality of modulation subcarriers. The D / A converter 60 converts the digital OFDM signal into an analog OFDM signal and outputs it to the transmission path. The amplitude control unit 70 adjusts the amplitude of the modulated subcarrier in accordance with the number of subcarriers selected by the subcarrier selection unit 90 so that the power of the analog OFDM signal becomes a predetermined value.

Description

OPDM transmitter and FM transmission method {OFDM TRANSMITTER AND OFDM TRANSMISSION METHOD}

The present invention relates to an OFDM transmission apparatus and an OFDM transmission method.

WO 2005/55479 discloses an Orthogonal Frequency Division Multiplexing (OFDM) transmitter, which transmits digital data using a multicarrier signal (OFDM signal) comprising a plurality of subcarriers having an orthogonal relationship with each other. An OFDM transmitter multiplexes a plurality of subcarriers modulated by digital data to generate a digital multicarrier signal. The digital multicarrier signal is converted into an analog multicarrier signal by a D / A converter and output to the transmission path.

In the OFDM transmitter disclosed in WO2005 / 55479, it is not considered to make the best use of the capability of the D / A converter by matching the maximum amplitude of the OFDM signal to the maximum amplitude that the D / A converter can accommodate.

SUMMARY OF THE INVENTION The present invention has been made in view of the above reasons, and an object of the present invention is to provide an OFDM transmitter and an OFDM transmission method capable of transmitting digital data using the capacity of a D / A converter to the maximum.

An OFDM transmission apparatus according to the present invention includes a subcarrier selection unit, a modulation unit, an OFDM signal generation unit, a D / A converter, and an amplitude control unit. The subcarrier selection unit selects a plurality of subcarriers used for transmission of digital data from subcarrier groups having an orthogonal relationship with each other. The modulation unit divides the digital data according to the number of the subcarriers selected by the subcarrier selection unit. In addition, the modulation unit modulates the plurality of subcarriers based on the divided digital data to generate a plurality of modulation subcarriers. The OFDM signal generation unit multiplexes the plurality of modulation subcarriers to generate a digital OFDM signal. The D / A converter converts the digital OFDM signal into an analog OFDM signal and outputs it to a transmission path. The amplitude control unit adjusts the amplitude of the modulation subcarrier in accordance with the number of subcarriers selected by the subcarrier selection unit so that the power of the analog OFDM signal is a predetermined value.

According to the present invention, even if the number of subcarriers used for transmission of the digital data is changed, the power of the analog OFDM signal maintains a predetermined value. Therefore, the digital data can be transmitted using the capacity of the D / A converter to the maximum.

In a preferred embodiment, there is a power detection unit for detecting power of the analog OFDM signal. The amplitude control unit adjusts the amplitude of the modulation subcarrier in accordance with the number of subcarriers selected by the subcarrier selection unit such that the power detected by the power detection unit becomes the predetermined value.

In this way, the power of the analog OFDM signal can be set to the predetermined value with good accuracy.

According to a preferred embodiment, there is provided a transmission path state obtaining unit for obtaining the transmission path state of each subcarrier. The amplitude control unit determines the good or bad of the transmission path state of the subcarrier based on the transmission path state of the subcarrier acquired by the transmission state acquisition unit. Further, the amplitude control unit reduces the amplitude of the modulated subcarrier corresponding to the subcarrier having a good transmission path state, and increases the amplitude of the modulated subcarrier corresponding to the subcarrier having a poor transmission path state.

According to a preferred embodiment, the communication accuracy is improved, and as a result, the communication speed is improved.

In a preferred embodiment, the predetermined value is the power of the analog OFDM signal when the amplitude of the digital OFDM signal is equal to the maximum value that the D / A converter can accept.

According to a preferred embodiment, the capacity of the D / A converter can be utilized to the maximum.

In a preferred embodiment, a transmission path state acquisition unit is provided for acquiring transmission path states of the respective subcarriers. The subcarrier selection unit selects the plurality of subcarriers used for transmission of the digital data from the subcarrier group based on the transmission path state of the subcarrier acquired by the transmission state estimation unit.

According to a preferred embodiment, the communication accuracy is improved, and as a result, the communication speed is improved.

The OFDM transmission method according to the present invention includes five steps. In the first step, a plurality of subcarriers used for transmission of digital data are selected from subcarrier groups having orthogonal relations with each other. In the second step, the digital data is divided according to the selected number of subcarriers, and the plurality of subcarriers are modulated based on the divided digital data to generate a plurality of modulated subcarriers. In a third step, the plurality of modulation subcarriers are multiplexed to generate a digital OFDM signal. In the fourth step, the digital OFDM signal is converted into an analog OFDM signal by a D / A converter and output to the transmission path. The fifth step is executed between the second step and the third step. In the fifth step, the amplitude of the modulation subcarrier is adjusted according to the number of the subcarriers selected in the first step so that the power of the analog OFDM signal is a predetermined value.

According to the present invention, even if the number of subcarriers used for transmission of the digital data is changed, the power of the analog OFDM signal maintains a predetermined value. Therefore, the digital data can be transmitted using the capacity of the D / A converter to the maximum.

1 is a block diagram of an OFDM transmission apparatus according to an embodiment of the present invention.
2 is an explanatory diagram of the operation of the OFDM transmitter.

An OFDM transmitter (hereinafter referred to as a "transmitter") 10 of an embodiment of the present invention shows digital data by a multicarrier signal (OFDM signal) using a plurality of subcarriers having different orthogonal relations with different frequencies from each other. To an OFDM receiver (hereinafter referred to as a "receiver"). An OFDM communication device comprising a transmitter 10 and a receiving device is used to perform packet communication by an OFDM modulated signal (OFDM signal). The transmission path between the transmitter 10 and the OFDM receiver may be wired or wireless.

The transmitter 10 includes an error correction code unit 20, a modulation unit 30, an interleaver 40, a signal generating unit 50, a D / A converter 60, an amplitude control unit 70, and a transmission path state. Acquisition unit (hereinafter referred to as "acquisition unit") 80, and subcarrier selection unit (hereinafter referred to as "selection unit") (90).

The acquisition unit 80 acquires the transmission path state of the subcarrier. For example, the acquisition unit 80 receives the transmission path state (receive state) of each subcarrier of the OFDM signal from the reception device. The transmission path state is, for example, an S / N ratio. In addition, the transmission path state may be a BER (Bit Error Rate).

The selection unit 90 selects a plurality of subcarriers used for transmission of digital data from subcarrier groups having an orthogonal relationship with each other.

Here, the higher the S / N ratio of the subcarrier is, the lower the bit error rate is. In other words, the higher the S / N ratio, the higher the accuracy of communication. Therefore, the selection unit 90 estimates that the transmission path state of the subcarrier is bad if the S / N ratio of the subcarrier is equal to or less than the first threshold value. Further, the selection unit 90 estimates that the transmission path state of the subcarrier is good if the S / N ratio of the subcarrier exceeds the first threshold value. The selection unit 90 selects a subcarrier having a good transmission path state without selecting a subcarrier having a poor transmission path state as a result of the estimation of the transmission path state. The result of selecting the subcarriers in the selection unit 90 is notified to the modulation unit 30. In the initial state before the acquisition unit 80 acquires the subcarrier transmission path state, the selection unit 90 selects all subcarriers. And the selection unit 90 may estimate the transmission path state of a subcarrier every fixed time. In addition, when the transmission path state hardly changes, the selection unit 90 may use the result estimated at the time of installation of the transmitter 10 afterwards.

The error correction code unit 20 adds an error correction code to the digital data (serial bit sequence) transmitted to the receiving apparatus and outputs it to the modulation unit 30. By adding an error correction code, the reliability of the communication system can be improved even when the transmission path is under adverse conditions.

The modulation unit 30 has a serial / parallel converter 31, a symbol mapper 32, and a plurality of subcarrier modulators 33.

The serial / parallel converter 31 generates parallel data by dividing the digital data to which the error correction code has been added according to the number of subcarriers selected by the selection unit 90 (hereinafter referred to as "selection number"). The number of parallel data is equal to the number of choices. In addition, the division of digital data is performed in symbol units. The number of bits represented by one symbol is determined by the modulation method. For example, in the case of Quadrature Phase Shift Keying (QPSK), one symbol corresponds to 2 bits. The serial / parallel converter 31 outputs parallel data to the symbol mapper 32.

The symbol mapper 32 converts each parallel data generated by the serial / parallel converter 31 into a complex symbol sequence (IQ signal) for modulating subcarriers. The complex symbol constituting the complex symbol sequence is represented by the form of a + jb (j is an imaginary unit) using the coefficient a of the in-phase component of the subcarrier and the coefficient b of the orthogonal component of the subcarrier. For example, in QPSK, four sinusoids (symbols) of 90 degrees out of phase are used. Each symbol is defined as a complex symbol. The complex symbol corresponds exclusively to the symbol. Table 1 shows the correspondence between the bit sequence and the complex symbol in QPSK. The symbol mapper 32 typically converts the divided data into a complex symbol sequence by referring to a data table showing a correspondence relationship between the bit sequence and the complex symbol. The symbol mapper 32 outputs each complex symbol sequence to the subcarrier modulator 33 corresponding to the subcarrier selected by the selection unit 90.

    a     b   00   1 / v2   1 / v2   01   -1 / v2   1 / v2   11   -1 / v2   -1 / v2   10   -1 / v2   -1 / v2

The subcarrier modulator 33 corresponds exclusively to the subcarriers included in the subcarrier group. The subcarrier modulator 33 modulates the subcarrier by the complex symbol sequence received from the symbol mapper to generate a modulated subcarrier. The subcarrier modulator 33 outputs the modulated subcarrier to the interleaver 40.

As described above, the modulation unit 30 divides the digital data according to the number of selections. The modulation unit 30 also modulates a plurality of subcarriers (subcarriers selected by the selection unit 90) based on the divided digital data to generate a plurality of modulation subcarriers.

The interleaver 40 replaces the order (symbol order) of the modulation subcarriers generated by the subcarrier modulator 33 and outputs them to the signal generation unit 50. By using the interleaver 40, the influence of the burst error can be reduced.

The signal generating unit 50 includes an inverse discrete Fourier transform unit 51, a normal serial converter 52, a guard interval adding unit 53, a real part extraction unit 54, and a frequency converter 55. ), A local oscillator 56, and a bandpass filter 57.

The inverse discrete Fourier transform unit 51 performs inverse discrete Fourier transform on a plurality of modulation subcarriers obtained from the interleaver 40 for each symbol to generate sample values of the symbols. The inverse discrete Fourier transform unit 51 normally outputs the sample values of the symbols to the serial converter 52.

Usually, the serial converter 52 generates serial data (hereinafter, referred to as a "complex baseband OFDM signal") by arranging sample values of symbols obtained from the inverse discrete Fourier transform unit 51 in series.

The guard interval adding unit 53 adds a guard interval to the complex baseband OFDM signal. By adding the guard interval, inter-code interference due to the multipath delayed wave can be prevented.

The real part extracting unit 54 extracts the real part from the complex baseband OFDM signal.

The frequency converter 55 converts the frequency of the complex baseband OFDM signal to generate a carrier band OFDM signal (digital OFMD signal). The frequency converter 55 performs frequency conversion by multiplying the complex baseband OFDM signal by the carrier wave [cos (2 pfct )] of the frequency fc output by the local oscillator 56. The frequency converter 55 outputs the digital OFDM signal to the D / A converter 60 through the band pass filter 57.

The band pass filter 57 removes the excess frequency from the digital OFDM signal.

As described above, the signal generation unit 50 generates a digital OFDM signal by multiplexing a plurality of modulation subcarriers.

The D / A converter 60 converts the digital OFDM signal into an analog OFDM signal and outputs it to the transmission path. In addition, the D / A converter 60 detects the power of the analog OFDM signal. The D / A converter 60 outputs the detection result of the power of the analog OFDM signal to the amplitude control unit 70. In other words, the D / A converter 60 functions as a power detection unit that detects the power of the analog OFDM signal.

The amplitude control unit 70 includes an amplitude determination unit 71 and an amplitude adjustment unit 72. The amplitude determination unit 71 determines a target value (hereinafter referred to as a "target amplitude value") of the amplitude of each modulation subcarrier. The amplitude determination unit 71 outputs the target amplitude value to the amplitude adjustment unit 72. The amplitude adjustment unit 72 controls the subcarrier modulator 33 so that the amplitude of each modulation subcarrier becomes the target amplitude value received from the amplitude determination unit 71.

Here, the OFDM signal is generated by multiplexing all modulated subcarriers corresponding to the plurality of subcarriers selected by the selection unit 90. Therefore, the amplitude of the OFDM signal depends on the amplitude of the modulation subcarrier. The power of the modulation subcarrier depends on the amplitude of the modulation subcarrier.

The amplitude determination unit 71 according to the selected number so that the power (corresponding to the total power of all modulated subcarriers) of the analog OFDM signal output from the D / A converter 60 becomes the target power (predetermined value). Determine the amplitude of each modulation subcarrier. For example, the amplitude determination unit 71 determines the target amplitude value of each modulation subcarrier so that the power of each modulation subcarrier matches the target power divided by the number of selections. Therefore, the amplitude of each modulation subcarrier becomes smaller when the number of selections is large and increases when the number of selections is small.

2A shows a state in which all subcarriers are used (initial state). In this case, the target amplitude value of each modulation subcarrier is set so that the total power of all modulation subcarriers becomes the target power. Here, it is assumed that the S / N ratio of the subcarriers in the frequency band W is equal to or less than the first threshold. In this case, as shown in FIG. 2B, the selection unit 90 does not select a subcarrier in the frequency band W. FIG. Therefore, the number of selections decreases from the initial state. Therefore, the amplitude determination unit 71 increases the target amplitude value of each modulation subcarrier so that the total power of the modulation subcarriers becomes the target power in accordance with the decrease in the number of selections.

Therefore, the power of each modulation subcarrier after the number of selections decreases increases by ΔP from the initial state, as shown in Fig. 2C. Therefore, the total power of all modulated subcarriers in the initial state and the total power of all modulated subcarriers when the number of selections decreases are equal (in other words, the power of the analog OFDM signal is constant regardless of the change in the number of selections. do). That is, the amplitude of the digital OFDM signal input to the D / A converter 60 is also constant regardless of the change (increase or decrease) in the number of selections.

In addition, the amplitude determination unit 71 corrects the target amplitude value in accordance with the transmission path state of each subcarrier. Specifically, the amplitude determination unit 71 determines the good or bad of the transmission path state of the subcarrier selected by the selection unit 90 based on the transmission path state of the subcarrier acquired by the acquisition unit 80. If the S / N ratio of the subcarrier is less than or equal to the second threshold, the amplitude determination unit 71 determines that the transmission path state of the subcarrier is bad. It is judged to be good. The second threshold is set at a value greater than the first threshold. That is, the amplitude determination unit 71 determines the good or bad of the transmission path state of the subcarrier selected by the selection unit 90.

The second threshold may be smaller than the first threshold. When the second threshold is smaller than the first threshold, the subcarrier used may be increased than when the second threshold is larger than the first threshold.

Then, the amplitude determination unit 71 refers to the result of the determination to reduce the target amplitude value of the modulation subcarrier corresponding to the subcarrier having a good transmission path state, and to modulate the subcarrier corresponding to the subcarrier with a poor transmission path state. Increase the target amplitude of the carrier. However, also in this case, the amplitude determination unit 71 determines the respective target amplitude values so that the total power of the modulation subcarriers matches the target power. What is necessary is just to set suitably how to change a target amplitude value according to a transmission path state. Moreover, you may change the range of change of a target amplitude value according to the good or bad of a transmission path state.

As described above, the amplitude control unit 70 of the transmitter 10 adjusts the amplitude of the modulation subcarriers in accordance with the number of selections so that the power of the analog OFDM signal becomes the target power.

Therefore, even if the number of subcarriers used for transmission of digital data increases or decreases, the power of the analog OFDM signal output to the transmission path matches the target power.

Here, the amplitude of the analog OFDM signal is limited by the specification of the communication system, the specification of the D / A converter 60, the legal regulations (for example, the regulation on the power of the radio signal), and the like. On the other hand, the amplitude of each subcarrier is determined by the number of subcarriers to be used and the transmission path state of the subcarriers. Even in the same OFDM system, specifications such as the number of subcarriers used by the communication system are different. In addition, there may be subcarriers that cannot be used for communication due to the influence of noise and attenuation.

In the transmitter 10 of the present embodiment, in order to adapt the amplitude of the subcarrier to the number of subcarriers actually used, the number of subcarriers to be used is used as a reference when determining the amplitude of the subcarrier. Therefore, according to the transmitter 10, waste of power consumption can be suppressed. In addition, by reducing the number of subcarriers used, the remaining power is supplied to other available subcarriers. Therefore, according to the transmitter 10, the communication speed can be improved. In addition, the transmitter 10 can be used in common for communication systems having different numbers of subcarriers to be used.

Here, the predetermined value is preferably the power of the analog OFDM signal when the amplitude of the digital OFDM signal is equal to the maximum value that the D / A converter 60 can accommodate. In this way, even if the number of selections is increased or decreased in accordance with the state of the transmission path, the capacity (for example, resolution) of the D / A converter 60 can be utilized to the maximum. In addition, it is preferable that the D / A converter 60 is configured such that the predetermined value is the maximum value of the power of the analog OFDM signal recognized by legal regulations. In this way, the communication speed can be maximized.

However, the power of the analog OFDM signal may change depending on the transmission path state of the subcarrier. In the above example, the amplitude control unit 70 adjusts the amplitude of the modulation subcarrier based on the power of the analog OFDM signal detected by the D / A converter 60. Therefore, the power change of the analog OFDM signal due to the transmission path state can be suppressed. Therefore, the power of the analog OFDM signal can be maintained at a predetermined value.

In the D / A converter 60, the relationship between the digital signal input to the D / A converter 60 and the analog signal output from the D / A converter 60 is the specification of the D / A converter 60. Determined by Therefore, the amplitude of the modulation subcarrier whose power of the analog OFDM signal is a predetermined value can be theoretically obtained. Therefore, it is not necessary to actually detect the power of the analog OFDM signal. However, as described above, the power of the analog OFDM signal may change depending on the transmission path state. Therefore, it is preferable to actually detect the power of the analog OFDM signal.

In addition, the amplitude control unit 70 reduces the amplitude of the modulation subcarrier corresponding to the subcarrier having a good transmission path state, and increases the amplitude of the modulation subcarrier corresponding to the subcarrier having a poor transmission path state.

That is, the amplitude control unit 70 allocates a part of the power of the subcarrier having a good transmission path state to the subcarrier having a poor transmission path state. Therefore, it is possible to improve the communication status of the subcarriers in poor transmission path conditions. Therefore, communication accuracy improves, and as a result, communication speed improves.

And the amplitude control unit 70 does not necessarily need to change the amplitude of a modulation subcarrier according to the good or bad of a transmission path state. In other words, the amplitude control unit 70 may be configured so that the amplitudes of the modulation subcarriers are all the same.

Further, the selection unit 90 selects a plurality of subcarriers used for transmission of digital data from the subcarrier group based on the transmission path state of the subcarrier acquired by the acquisition unit 80. Therefore, it is possible to avoid using a subcarrier that cannot transmit digital data. Therefore, the transmitter 10 can prevent waste of power. In addition, communication accuracy is improved, and as a result, communication speed is improved.

In the above example, the selection unit 90 automatically selects a plurality of subcarriers used for transmission of digital data from the subcarrier group based on the transmission path state of the subcarriers. However, the selection unit 90 may be configured to select a subcarrier in accordance with an input from the outside. As a method of inputting from the outside, the method of manual input or the method of automatic input can be considered. In the manual input method, a predetermined value determined using an external device is input to the selection unit 90 using an external input device such as a button or a keyboard. In the automatic input method, an external computing device that determines the set value directly inputs the set value to the selection unit 90.

In addition, the OFDM transmission method of an embodiment of the present invention includes the following five steps, as can be seen from the operation of the transmitter 10 described above. In the first step, a plurality of subcarriers used for transmission of digital data are selected from subcarrier groups having orthogonal relations with each other. In the second step, digital data is divided according to the selected number of subcarriers. In the second step, the plurality of subcarriers are modulated based on the divided digital data to generate a plurality of modulated subcarriers. In a third step, a plurality of modulation subcarriers are multiplexed to generate a digital OFDM signal. In the fourth step, the digital OFDM signal is converted into an analog OFDM signal by a D / A converter and output to the transmission path. Here, the fifth step is executed between the second step and the third step. In the fifth step, the amplitude of the modulated subcarrier is adjusted according to the number of subcarriers selected in the first step so that the power of the analog OFDM signal is a predetermined value.

In the above-described OFDM transmission method, even if the number of subcarriers used for transmission of digital data is increased or decreased, the power of the analog OFDM signal output to the transmission path is controlled to a predetermined value. Therefore, according to the above-described OFDM transmission method, digital data can be transmitted by making full use of the capability of the D / A converter 60.

Claims (6)

In an OFDM transmitter,
A subcarrier selection unit for selecting a plurality of subcarriers used for transmission of digital data from subcarrier groups having an orthogonal relationship with each other;
A modulation unit for dividing the digital data according to the number of the subcarriers selected by the subcarrier selecting unit, and modulating the plurality of subcarriers based on the divided digital data to generate a plurality of modulation subcarriers;
An OFDM signal generation unit for multiplexing the plurality of modulation subcarriers to generate a digital OFDM signal; And
A D / A converter converting the digital OFDM signal into an analog OFDM signal and outputting the same to a transmission path
Including;
An amplitude control unit for controlling the amplitude of each of said plurality of modulation subcarriers,
The amplitude control unit is configured to adjust the amplitude of each of the modulation subcarriers according to the number of subcarriers selected by the subcarrier selection unit such that the power of the analog OFDM signal is a predetermined value transmitter. The method of claim 1,
A power detection unit configured to detect power of the analog OFDM signal,
The amplitude control unit is configured to adjust the amplitude of each of the modulation subcarriers in accordance with the number of the subcarriers selected by the subcarrier selection unit such that the power detected by the power detection unit becomes the predetermined value. OFDM transmitter. The method of claim 1,
A transmission path state obtaining unit configured to obtain a transmission path state of each subcarrier,
The amplitude control unit determines whether the transmission path state of the subcarrier is good or bad based on the transmission path state of the subcarrier acquired by the transmission path state acquisition unit, and corresponds to the subcarrier in which the transmission path state is good. And an amplitude of the modulation subcarrier to be small, and an amplitude of the modulation subcarrier corresponding to the subcarrier having a poor transmission path state. The method of claim 1,
And said predetermined value is defined as the power of said analog OFDM signal when the amplitude of said digital OFDM signal is equal to a maximum value that said D / A converter can accommodate. The method of claim 1,
A transmission path state acquisition unit for acquiring transmission path states of the respective subcarriers,
The subcarrier selection unit is configured to select the plurality of subcarriers used for transmission of the digital data from the subcarrier group based on the transmission path state of the subcarrier acquired by the transmission state estimation unit. OFDM transmitter. In the OFDM transmission method,
Selecting a plurality of subcarriers used for transmission of digital data from subcarrier groups having orthogonal relations with each other;
Dividing the digital data according to the selected number of subcarriers, and modulating the plurality of subcarriers based on the divided digital data to generate a plurality of modulated subcarriers;
Generating a digital OFDM signal by multiplexing the plurality of modulated subcarriers; And
A fourth step of converting the digital OFDM signal into an analog OFDM signal and outputting the analog OFDM signal to a transmission path
Including;
A fifth step between the second step and the third step,
In the fifth step, adjusting the amplitudes of the plurality of modulation subcarriers according to the selected number of subcarriers such that the power of the analog OFDM signal is a predetermined value.

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